Project description:NAD is a ubiquitous electron carrier essential for energy metabolism and the post-translational modification of numerous regulatory proteins. Perturbation of NAD metabolism is considered detrimental to health, with NAD depletion commonly thought to promote aging. However, to what extent normal NAD concentration can be decreased without deleterious repercussions is unclear. Here, we describe a mouse model where NAMPT-mediated NAD+ biosynthesis is disrupted in adult skeletal muscle. The resulting 85% decrease in muscle NAD+ abundance did not cause tissue degeneration or dysfunction, as reflected in its unchanged morphology, contractility, and exercise tolerance. The lack of defects was corroborated by intact mitochondrial respiratory capacity and unaffected muscle transcriptomic and proteomic profiles. Furthermore, lifelong NAD depletion did not accelerate muscle aging or impair whole-body metabolism. Collectively, these findings demonstrate that NAD depletion does not drive the age-related decline in skeletal muscle function.

Project description:NAD is a ubiquitous electron carrier essential for energy metabolism and the post-translational modification of numerous regulatory proteins. Perturbation of NAD metabolism is considered detrimental to health, with NAD depletion commonly thought to promote aging. However, the extent to which cellular NAD concentration can be decreased without deleterious repercussions is unclear. We generated a mouse model where nicotinamide phosphoribosyltransferase (NAMPT)-mediated NAD+ biosynthesis is disrupted in adult skeletal muscle. The resulting 85% decrease in muscle NAD+ abundance was associated with preserved tissue integrity and functionality, as demonstrated by its unchanged morphology, contractility, and exercise tolerance. This lack of defects was corroborated by intact mitochondrial respiratory capacity and unaffected muscle transcriptomic and proteomic profiles. Furthermore, lifelong NAD depletion did not accelerate muscle aging or impair whole-body metabolism. Collectively, these findings indicate that NAD depletion does not contribute to age-related decline in skeletal muscle function.

Project description:Skeletal muscle weakness is linked to many adverse health outcomes. Current research to identify new drugs has often been inconclusive due to lack of adequate cellular models. We have previously developed a scalable monolayer system to differentiate human embryonic stem cell (hESC) into mature skeletal muscle cells (SkMCs) within 26 days without cell sorting or genetic manipulation. Here, building on our previous work, we show that differentiation and fusion of myotubes can be further enhanced using the anabolic factors testosterone (T) and follistatin (F) in combination with a cocktail of myokines (C). Importantly, combined TFC treatment significantly enhanced both hESC-SkMC fusion index and expression of various skeletal muscle markers including the protein Myosin Heavy Chain (MyHC). Transcriptomic and proteomic analysis revealed oxidative phosphorylation as the most up-regulated pathway, suggesting energy metabolism is coupled to enhanced muscle differentiation. This cellular model will be a powerful tool for studying in vitro myogenesis and for drug discovery to further enhance muscle development or treat muscle diseases.

Project description:the expression of TF MEF2C is decreased in skeletal muscle of PRR14-KO mice,which displays sarcopenia phenotype. Meanwhile, increasing MEF2C's expression in skeletal muscle lessens the phenotype.

Project description:This project aimed to assess the role of pharmacological inhibition of the aryl hydrocarbon receptor (AhR) on skeletal muscle and cortical bone health in aged mice. As part of a broader systems biology approach, proteomic profiling was employed to investigate molecular mediators of neuromuscular junction (NMJ) function in skeletal muscle tissue. The study compared vehicle-treated versus BAY2416964-treated aged mice, revealing key differentially expressed proteins involved in axonal development and NMJ stability.

Project description:The aim of the study was to investigate how short-term fasting affects whole-body energy homeostasis and skeletal muscle energy/nutrient-sensing pathways and transcriptome in humans. For this purpose, twelve young healthy men were studied during a 24-hour fast. Skeletal muscle biopsies were collected and analyzed at baseline and after 4, 10 and 24h of fasting. As expected, fasting induced a time-dependent decrease in plasma insulin and leptin levels, whereas levels of ketone bodies and free fatty acids increased. This was associated with a metabolic shift from glucose towards lipid oxidation. Transcriptome profiling identified genes that were significantly regulated by fasting in skeletal muscle at both early and late time-points. Collectively, our study provides a comprehensive map of the main energy/nutrient-sensing pathways and transcriptomic changes during short-term adaptation to fasting in human skeletal muscle

Project description:NAD is a ubiquitous electron carrier essential for energy metabolism and the post translational modification of numerous regulatory proteins. Perturbation of NAD metabolism is considered detrimental to health, with NAD depletion commonly thought to promote aging. However, the extent to which cellular NAD concentration can be decreased without deleterious repercussions is unclear. We generated a mouse model where nicotinamide phosphoribosyltransferase (NAMPT)-mediated NAD+ biosynthesis is disrupted in adult skeletal muscle. The resulting 85% decrease in muscle NAD+ abundance was associated with preserved tissue integrity and functionality, as demonstrated by its unchanged morphology, contractility, and exercise tolerance. This lack of defects was corroborated by intact mitochondrial respiratory capacity and unaffected muscle transcriptomic and proteomic profiles. Furthermore, lifelong NAD depletion did not accelerate muscle aging or impair whole-body metabolism. Collectively, these findings indicate that NAD depletion does not contribute to age related declines in skeletal muscle function.

Project description:Human mutations in the ANK2 gene, which encodes ankyrin B (AnkB), lead to age- and diet-induced metabolic syndrome in mice. To investigate the contribution of skeletal muscle (SKM) AnkB to systemic energy balance and metabolic homeostasis, we developed skeletal muscle (SKM)-specific AnkB knockout (KO) (Ank2f/f; HSA-Cre+) mice. Physiological,cellular, biochemical and transcriptional characterization of these mice uncovered a muscle-autonomous role of AnkB in maintaning mitochondria health and muscle energetic homeostasis via the regulation of mitochondrial dynamics and sarcoplasmic reticulum (SR) organization.

Project description:a 4D-label free detection method using LC-MS/MS was employed to analyze the skeletal muscle samples from different pig breeds

Project description:Thyroid hormones are important for homeostatic control of energy metabolism and body temperature. Although skeletal muscle is considered an important site for thyroid action, the contribution of thyroid hormone receptor signaling, in muscle, to whole-body energy metabolism and body temperature has not been resolved. Here, we show that thyroid hormone-induced increase in energy expenditure requires thyroid hormone receptor alpha 1 (TRa1) in skeletal muscle, but that thyroid hormone induced elevation in body temperature is independent of muscle-TRa1. In slow-twitch soleus muscle, ablation of TRa1 leads to an altered fiber type composition toward a more oxidative phenotype, which, however, does not influence running capacity or motivation to voluntary running. RNA-sequencing of soleus muscle from WT mice and TRaHSACre mice revealed differentiated transcriptional regulation of genes associated with muscle thermogenesis, such as sarcolipin and UCP3, thus providing molecular clues pertaining to the mechanistic underpinnings of TRa1-linked control of whole-body metabolic rate. Together, this work establishes a fundamental role for skeletal muscle in thyroid hormone-stimulated increase in whole-body energy expenditure.